Gas meter including a synthetic membrane

ABSTRACT

A gas meter includes a housing made of thermoplastic material having an inside wall defining two measuring chambers and a deformable membrane disposed between the two measuring chambers. The deformable membrane is formed from a film of thermoplastic elastomer material bonded to a synthetic fiber sheet. The periphery of the membrane is hot-welded to the wall between the two measuring chambers to form a gas-tight seal between the chambers. A mechanical drive train includes at least one lever having a hinged portion made from a thermoplastic material which is hot-welded to the middle of the membrane. The train drives a mechanical distributor disposed outside the housing.

The present invention relates to a method of making synthetic membranesfor a gas meter, and to gas meters including a membrane obtained by thesaid method.

BACKGROUND OF THE INVENTION

It is well known that so-called "chamber" gas meters contain at leastone deformable membrane which separates two adjacent displacementmeasuring chambers. The gas whose flowrate is to measured is injectedinto and evacuated from the measuring chambers and causes the membraneto move back and forth. Membrane motion is transmitted by a mechanicalsystem to a counter which thus serves to display the quantity of gaswhich has passed through the measuring chambers. The periphery of themembrane is fixed to the common wall of the chambers and the centralportion of the membrane is fixed to the mechanism which connects themembrane to the counter.

In order for the gas meter to supply the desired measuring accuracy, itis necessary for the membrane itself to have well-specified properities.It must be gastight to a very high degree. For example, the membranemust be able to withstand a pressure of 50 millibars for a period of oneminute with practically no leakage. The membrane must also be veryflexible and it must be able to withstand mechanical fatigue as testedby endurance tests. For example, the membrane must be capable ofwithstanding 2,000,000 cycles at a frequency of 100 cycles per minutewithout suffering significant deterioration. Further, the membrane mustnot suffer from exposure to the various hydrocarbons which may bepresent in the gas to be measured. In particular, the tests require amembrane to withstand a mixture of toluene and heptane.

Traditionally, this type of meter has made use of membranes made fromspecially selected and treated goatskin. They are relatively expensive.Because of the above-mentioned requirements, it has long remaineddifficult to make membranes out of synthetic material which have thedesired characteristics. Thus proposals have already been made to makethe membrane from a structure of woven fibers, e.g. polyester fiberswith the structure being impregnated with layers of synthetic rubber.Such rubber-impregnated structures present storage problems by virtue ofself-vulcanization phenomena which occur over time at ambienttemperature. This solution suffers from the drawback that the syntheticrubber must be vulcanized in order to acquire its final properties. Suchvulcanization consumes non-negligible quantities of energy. Further, asis well known, synthetic rubber processing gives rise to non-negligiblepollution risks.

Proposals have also been made to provide membranes using a single layerof plastic material. None of these attempts has yet given results whichare satisfactory for use in a gas meter.

In order to remedy these drawbacks, an aim of the invention is toprovide a method of making membranes which are usable in gas meters andwhich do not require vulcanization techniques, while neverthelessenabling membranes to be obtained whose mechanical strength andflexibility are sufficient, while still remaining chemically inertrelative to materials likely to be present in the gas to be measured.

SUMMARY OF THE INVENTION

In accordance with the invention, this aim is achieved by a method ofmaking a gas meter membrane comprising the following steps:

a film of thermoplastic elastomer material is disposed opposite to oneface of a synthetic fiber structure of substantially constant thickness;

said elastomer material is raised to its softening temperature;

simultaneously, pressure is exerted on the assembly constituted by saidstructure and said film in order to cause said elastomer material toadhere to said structure, to close the interstices in said structure,and to completely cover said face of the structure by deformation ofsaid film;

said pressure is then removed and the resulting complex is allowed tocool; and

said complex is shaped in order to obtain a membrane of the desiredshape.

The resulting membrane has sufficient flexibility and mechanicalstrength and does not require any vulcanization.

In a preferred implementation of the method, a film of thermoplasticelastomer material is disposed on either side of the synthetic fiberstructure and pressure is exerted on the assembly constituted by thestructure and the two films of thermoplastic elastomer.

The resulting membrane is completely symmetrical in structure.

Also preferably, the material constituting the synthetic fibers is apolyester, and said structure is woven.

Also preferably, the thermoplastic elastomer film is a polyurethane.

Another aim of the invention is to provide a gas meter in which fixingthe periphery of the membrane to the body of the meter in sealed manneris simplified. To achieve this aim, the meter housing is made of athermoplastic material, the membrane is obtained by performing themethod in accordance with the invention as defined above, and theperiphery of the membrane is hot welded to the housing.

BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics and advantages of the invention appear moreclearly from reading the following description of severalimplementations of the invention given by way of nonlimiting example.The description refers to the accompanying drawings, in which:

FIGS. 1a and 1b illustrate a first embodiment of a synthetic membrane inaccordance with the invention shown in section on a vertical plane;

FIG. 2a and 2b show a variant embodiment of the membrane in verticalsection views;

FIG. 3 is a section through a shaped membrane in accordance with theinvention;

FIG. 3a is a vertical section through a machine for shaping a membrane;

FIG. 3b is a vertical section through a machine for simultaneouslymaking a complex and shaping it;

FIG. 4 is a partially cutaway elevation view of a gas meter inaccordance with a first implementation of the invention;

FIG. 5 is a section view on a line V--V of FIG. 4; and

FIG. 6 is a view in partial section of a variant embodiment of a gasmeter in accordance with the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

Reference is made initially to FIGS. 1a and 1b while describing a firstembodiment of a synthetic membrane for gas meters in accordance with theinvention. The initial structure is constituted by a structure ofsynthetic fibers given an overall reference 10, and by a film ofthermoplastic elastomer material 12. Preferably, the structure 10 ofsynthetic fibers 11 is of the woven type, however it could be non-woven,or it could be knitted. In the particular example described, the fibers11 are made of polyester, and the weight of these fibers expressed ingrams per 10,000 meters of fiber is about 50. More precisely, the fibersused are 33 decitex fibers (33 g/10,000 m of fiber). The mesh of thewoven cloth may be square having a side which is about 2/10 millimeterslong. The thickness of the cloth is substantially constant and about10/10-ths of a millimeter. Polyamide fibers could also be used. Thethermoplastic film 12 is preferably the material sold under thetrademark PLATILON U by the German PLATE BONN corporation. This materialis a polyurethane. Preferably, the film is about 2.5 to 3/100-ths of amillimeter thick. Alternatively, the film could also be a thermoplasticpolyester elastomer based on a polyether ester, for example the materialsold under the trademark ARNITEL by the Dutch AKZO PLASTICS corporation.

In order to make the membrane from the structure 10 and the film 12, thestructure 10 is placed on a plate 14 and the film 12 is placed on onethe faces 10a of the structure 10. A second plate 14 containing heatermeans symbolized by a heater resistance 16 is pressed against the stackconstituted by the structure 10 and the film 12 to obtain apredetermined pressure while raising the polyurethane film 12 to itssoftening temperature. In the particular example described, thesoftening temperature is about 170° C., and the pressure is about 50bars. The pressure is maintained using the plate 14 for a period ofabout 1 minute, and then the pressure is removed and the resultingcomplex 18 is allowed to cool. Since the thermoplastic material has beenraised to its softening temperature, its final structure as shown inFIG. 1b clearly indicates that the plastic material having an overallreference 20 is deformed and penetrates into the interstices such as 22defined by the fibers 11 of the structure 10. However, it should beobserved that the plastic material 20 completely covers the face 10a ofthe structure 10 against which the thermoplastic film was disposed. Theresulting complex 18 is completely gas-tight and has the requiredmechanical strength to withstand the set number of cycles whileretaining sufficient flexibility due, in particular, to the thickness ofthe plastic material 20. The membrane per se is obtained from saidcomplex by shaping the complex. This consists essentially in giving thecomplex a curved shape and in cutting out the periphery of the membraneto give it the required size. These operations may be performed using amold which presents the desired final shape of the membrane. The mold isheated to a temperature which is below the softening temperature of thecomplex, e.g. 120° C. to 130° C. for a period of 10 minutes. The mold isthen allowed to cool together with the membrane before unmolding theshaped membrane.

FIG. 3 shows a shaped membrane in accordance with the invention. Themembrane 30 includes a substantially plane flange 32, a bottom 34 whichis also substantially plane, and a bellows-forming portion 36. In orderto simplify FIG. 3, it does not show the structure of the membrane whichis the same as that shown in FIGS. 1b and 2b.

Other tests have shown that a structure having a substantially squaremesh with a side of up to 3 to 4 millimeters may also be used.

In the above-described example, the membrane is obtained discontinuouslyby means of a fixed plate 14 and a moving plate 15. Naturally, themembrane could be obtained continuously by using glazing rollers.

FIG. 3a is a section through a machine for shaping a pre-existingcomplex to obtain a membrane for a gas meter. The machine comprises asupport 300 in the form of a frame whose size corresponds to the desiredsize of the plane flange round the membrane to be shaped. The support300 stands on a fixed plate 302 of a press. The complex 304 to be shapedrests on the top of the frame 300. The machine also includes a movingassembly 306 including a thrust member 308 and a male mold portion 310.The thrust member 308 is mounted on the moving plate of the press. Themember 308 is also in the form of a frame so that when lowered it clampsthe periphery of the complex between itself and the rim 300a of thesupport 300.

The active end 310a of the mold portion 310 has a shape corresponding tothat which is to be given to the membrane. The mold portion 310 includesheater means represented by a heater resistance 312.

The operation of the machine follows from the above description.Initially, the thrust member 306 is lowered to clamp the periphery ofthe complex 304. The male mold portion is then lowered to shape themembrane against its active face 310a by the combined actions of heatingand pressure. Its downward travel is limited stop lugs 311 projectinglaterally therefrom. Subsequently the heater is turned off and themembrane is unmolded after a suitable cooling period has elapsed.

FIG. 3b shows a variant of the FIG. 3a machine, in which the samemachine simultaneously makes the complex and shapes it. This machine isvery similar to that shown in FIG. 3a and the same reference numeralshave been used for parts which are common to both machines.

The difference lies in the fact that the support frame 300 is partiallyfilled with elastomer material 320. The elastomer material may bepolyurethane or silicone. It is cast into the support 300 and its topface 320a is given a hollow shape complementary to the active end of themale mold portion 310. The fill 320 thus constitutes a female moldportion which is deformable to some extent.

The three sheets from which a membrane is to be built up, namely thefiber structure 326 sandwiched between the thermoplastic films 322 and324, are placed on the support 300.

The thrust member 308 is lowered first, followed by the male moldportion 310. The male mold portion 310 is heated by means of the heaterresistance 312 to raise the thermoplastic sheets 322 and 326 to theirsoftening temperature. Simultaneously, by virtue of the female moldportion 320, the threesheet sandwich is pressed together, firstly toconstitute the said complex and then to shape the membrane. Unmoldingtakes place as already described with reference to FIG. 3a.

It is important to observe that the adherence of the elastomer materialon the basic woven structure is obtained by hot melting which thusavoids the need to use an adhesive. Further, since the elastomer used isof the thermoplastic type, there is no need for any vulcanizationoperation in order to reach its final state.

As can be seen in FIGS. 2a and 2b, it is preferable to make membranewhich is symmetrical in structure by using a woven structure 10identical to the structure 10 in FIG. 1a together with two thermoplasticelastomer films which are respectively referenced 26 and 28 and whichare initially disposed on either side of the structure 10. Boththermoplastic films 26 and 28 are raised to their softening temperatureby the same operation as described above with reference to FIGS. 1a and1b in order to deform the films against the base structure 10 and obtaina complex such as that shown in FIG. 2b. In this case, both faces of thebase structure are covered in hot meltable material 20. The membranethus obtained from a polyester cloth and films of thermoplastic materialhaving the above-described characteristics, is about 15/100-ths of amillimeter thick.

As is well known, in order to obtain a membrane which can actually beused in a gas meter, the complex must be cut out and it must be giventhe required shape instead of its initial plane shape. Thesemembrane-shaping operations may be performed conventionally as describedabove.

Instead of using a woven structure as described above, a knittedstructure may be used. Such structures are well known per se. A knittedstructure is particularly suitable for use with a single thermoplasticfilm.

In addition to the advantages already mentioned, a membrane obtained bythe method in accordance with the invention is easier than prior artmembranes to fix on the walls of the meter's measuring chamber providedthat said walls are made of a plastic material. Using a conventionalmembrane, the periphery of the membrane is generally fixed to the wallof the measuring chamber by means of a retaining washer which is fixedto the wall, with the periphery of the membrane being clamped betweenthe washer and a shoulder in the wall, as described in European patentapplication No. 128 838 for a gas meter and filed in the name of thepresent Applicant. A membrane in accordance with the invention may bedirectly fixed to the wall in a gastight manner by hot welding.

Reference is now made to FIGS. 4 and 5 for describing an embodiment of agas meter in accordance with the invention, said embodiment includingtwo membranes obtained by the method of the invention.

The meter has exactly the same structure as the meter described in theabove-mentioned European patent application, except that the followingitems are different: the membranes forming the bellows; the method offixing the bellows to the meter housing; and the ends of the levers ofthe meter drive chain where connected to the bellows. The overallstructure of the meter is thus recalled only briefly.

The meter comprises a gastight outer envelope A made up of two shells 50and 52 and provided with a gas inlet nozzle 54 for the gas to bemeasured and a gas outlet nozzle 56. Inside the envelope A, the meterincludes a measuring unit B comprising a housing D and a rotarydistributer E. Finally, the meter includes a counter F.

The housing D comprises a central block 60, two side covers 62 and 64,and a distribution cover 66. The central block 60 and the side covers 60and 62 are made of a thermoplastic material. For example they may bemade of the thermoplastic material sold under the trademark Nylon or thematerial sold under the trademark Delrin. The side covers 62 and 64 arewelded to the central block 60 in order to define two measuringcompartments 68 and 70. The measuring compartment 68 is divided into twomeasuring chambers 72 and 74 by a deformable bellows 76. Similarly, themeasuring compartment 70 is divided into two measuring chambers 78 and80 by a deformable bellows 82. In accordance with the invention, thebellows 76 and 82 are constituted by shaped membranes and as definedabove with reference to FIGS. 1 to 3. The rim 84 of the membraneconstituting the bellows 76 is hot welded to a shoulder 86 provided onthe portion of the central block 60 which faces towards the side cover62. Similarly the rim 88 of the membrane constituting the bellows 82 ishot welded to a shoulder 90 provided in the portion of the central block60 facing the side cover 64. The hot welding is preferably performedusing a hot tool which has the same general shape as the periphery ofthe membrane and which is applied thereagainst. In order to avoid themembrane from adhering to the end of the tool while being heatedthereby, said end is protected by a synthetic coating whose softeningtemperature is considerably higher than that of the membrane. Forexample the material sold under the trademark "Teflon" may be used. Thehot welding could also be performed by utrasonic welding.

It will be understood that this form of gastight fixing to the peripheryof the membrane is made possible by the presence of the elastomer filmwhich constitutes the outside face of the membrane and which is made ofa thermoplastic, as is the meter housing. This method of fixing thebellows to the meter housing is much simpler than that described in theabovementioned European patent application, and nevertheless providesvery good sealing.

Returning to the description of the housing D, it can be seen that thedistribution cover 66 defines four openings, with only the openings 100and 102 being visible in FIG. 5, together with a central gas outletorifice 104. Each opening is connected to a respective one of thechambers 68, 72, 78, and 80 via passages formed through the centralblock 60. The central orifice 104 is connected to the outlet nozzle viaan internal passage 106 and a duct 108.

The rotary distributor E is pivotally mounted about an axis XX' andslides over the top face of the distribution cover 66. The distributor Eis described in detail in the abovementioned European patent applicationand serves to put each opening into communication with the outletorifice 104 and with the inside of the envelope A into which the gas tobe measured flows. Thus, each chamber 71, 74, 78, and 80 is successivelyconnected to the gas inlet 54 and to the gas outlet 56. In order toensure that the displacements of the bellows 76 and 82 and the rotationof the distributor E occur in synchronism, the measuring unit includestwo drive-transmitting assemblies, with each assembly connecting one ofthe bellows 76 and 82 to the distributor E. Thus, the bellows 76 isconnected inside the chamber 68 to a lever 120 having one end hinged toa bellows plate 122. In accordance with the present invention, thebellows plate 122 is made of thermoplastic material. The plate 122 ishot welded by means of a heater of the same kind as that alreadydescribed for welding the periphery of the membrane to the meterhousing, and the connection between the bellows plate and the membraneis much simpler than that described in the above-mentioned Europeanpatent application.

Returning to the first mechanical drive chain, it can be seen that italso includes a shaft 126 whose bottom end is fixed to rotate with thesecond end of the lever 120. The top end of the shaft 126 is fixed toanother lever 128 and the other end of the lever 128 is hinged to athird lever 130. One end of the lever 130 is pivotally mounted on a part132 which constitutes a handle and which is fixed to rotate with thedistributor E. The other mechanical drive chain is identical to thefirst and it comprises, in particular, a bellows plate 134 ofthermoplastic material hot welded to the synthetic membrane constitutingthe bellows 82. The end of a lever 136 is pivotally mounted to thebellows plate 134.

The counter F for displaying the measured quantity of gas is connectedto the handle-forming part 132 by a set of toothed wheels 140, 142, andby a magnetic transmission 144. These transmission means are describedin greater detail in European patent application No. 128 838.

The operation of the meter described above with reference to FIGS. 4 and5 is identical to the operation of the meter described in theabove-mentioned European patent application.

The person skilled in the art will understand that the present inventionis in no way restricted to the particular type meter described above.The invention is applicable to any gas meter having chambers in whichtwo measuring chambers are separated by a flexible membrane, with themeter housing being made of a thermoplastic material in order to enabledirect hot welding between the periphery of the membrane and the insidewall of the chambers. In particular, the invention is applicable tometers have some number of measuring chambers other than four. It isalso applicable to the case where the distributor uses rectilinearmotion rather than rotary motion as described above.

It should be added that in the case of the meter described above withreference to FIGS. 4 and 5, the welding surfaces between the side covers62 and 64 and the central block 60 are not plane, which is why it wasnecessary to provide shoulders to which the peripheries of the bellowscould be welded.

FIG. 6 is a diagram illustrating a portion of a variant embodiment ofthe meter.

In this figure, a portion of a central block 200 is shown in simplifiedmanner together with a side cover 202 for defining measuring chambers204 and 206. The side cover 204 has a welding face 208 against thecentral block 200, which face is plane. Similarly, the portion of thecentral block 200 shown in FIG. 6 has a welding face 210 which is alsoplane. FIG. 6 shows that the chambers 204 and 206 are separated by adeformable bellows 212 constituted by the above-described syntheticmembrane. The bellows 212 includes a plane rim 214 which is hot weldedbetween the welding faces 208 and 210 of the central block 200 and theside cover 202. Similarly, a bellows plate 216 of thermoplastic materialis hot welded to the plane central portion 218 of the bellows. One endof a lever 220 belonging to the mechanical drive chain is fixed to saidbellows plate.

It will be understood that the use of synthetic membranes for making gasmeters not only simplifies the assembly of the bellows in the meterhousing, but also eliminates certain membrane punching operations, inparticular the operations required for making holes to which the bellowsplates are fixed or to which the bellows-retaining washers are fixed.

I claim:
 1. A gas meter comprising:a housing made of thermoplasticmaterial having an inside wall and defining two measuring chambers; adeformable membrane disposed in said housing between said chambers; saidmembrane being made of a complex comprising a film of thermoplasticelastomer material disposed opposite to one face of a synthetic fiberstructure of substantially constant thickness, said elastomer materialadhering to said film structure and covering said face of the filmstructure; said membrane further including a periphery which is fixed tosaid inside wall by hot-welding to form a gas-tight seal between theperiphery of said membrane and said inside wall; a moving distributordisposed outside said housing; and a mechanical drive train forconnecting said membrane to said distributor, said drive train includingat least one lever and a part for connecting one end of said lever tosaid membrane in a hinged manner, said part being made of athermoplastic material which is hot-welded to the middle of saidmembrane.
 2. The gas meter of claim 1 wherein the membrane comprises asecond film of thermoplastic elastomer material disposed on a face ofsaid fiber structure opposite said one face.
 3. The gas meter of claim 1wherein the thermoplastic elastomer material is a polyurethane.
 4. Thegas meter of claim 1 wherein said fibers of said structure are made ofpolyester.
 5. The gas meter of claim 4 wherein said fibers are made ofpolyamide.
 6. A gas meter of claim 1, wherein said fiber structure iswoven and has a mesh which is substantially square with a side lying inthe range of 0.2 millimeter to 4 millimeters.
 7. The gas meter of claim1, wherein said films of thermoplastic elastomer material are 25 to 30μm thick.
 8. A gas meter according to claim 1, wherein said fiberstructure is knitted.